зеркало из https://github.com/mozilla/gecko-dev.git
289 строки
12 KiB
C++
289 строки
12 KiB
C++
/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "Blur.h"
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#include <arm_neon.h>
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namespace mozilla {
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namespace gfx {
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MOZ_ALWAYS_INLINE
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uint16x4_t Divide(uint32x4_t aValues, uint32x2_t aDivisor)
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{
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uint64x2_t roundingAddition = vdupq_n_u64(int64_t(1) << 31);
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uint64x2_t multiplied21 = vmull_u32(vget_low_u32(aValues), aDivisor);
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uint64x2_t multiplied43 = vmull_u32(vget_high_u32(aValues), aDivisor);
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return vqmovn_u32(vcombine_u32(vshrn_n_u64(vaddq_u64(multiplied21, roundingAddition), 32),
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vshrn_n_u64(vaddq_u64(multiplied43, roundingAddition), 32)));
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}
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MOZ_ALWAYS_INLINE
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uint16x4_t BlurFourPixels(const uint32x4_t& aTopLeft, const uint32x4_t& aTopRight,
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const uint32x4_t& aBottomRight, const uint32x4_t& aBottomLeft,
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const uint32x2_t& aDivisor)
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{
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uint32x4_t values = vaddq_u32(vsubq_u32(vsubq_u32(aBottomRight, aTopRight), aBottomLeft), aTopLeft);
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return Divide(values, aDivisor);
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}
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MOZ_ALWAYS_INLINE
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void LoadIntegralRowFromRow(uint32_t *aDest, const uint8_t *aSource,
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int32_t aSourceWidth, int32_t aLeftInflation,
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int32_t aRightInflation)
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{
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int32_t currentRowSum = 0;
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for (int x = 0; x < aLeftInflation; x++) {
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currentRowSum += aSource[0];
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aDest[x] = currentRowSum;
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}
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for (int x = aLeftInflation; x < (aSourceWidth + aLeftInflation); x++) {
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currentRowSum += aSource[(x - aLeftInflation)];
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aDest[x] = currentRowSum;
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}
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for (int x = (aSourceWidth + aLeftInflation); x < (aSourceWidth + aLeftInflation + aRightInflation); x++) {
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currentRowSum += aSource[aSourceWidth - 1];
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aDest[x] = currentRowSum;
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}
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}
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MOZ_ALWAYS_INLINE void
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GenerateIntegralImage_NEON(int32_t aLeftInflation, int32_t aRightInflation,
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int32_t aTopInflation, int32_t aBottomInflation,
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uint32_t *aIntegralImage, size_t aIntegralImageStride,
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uint8_t *aSource, int32_t aSourceStride, const IntSize &aSize)
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{
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MOZ_ASSERT(!(aLeftInflation & 3));
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uint32_t stride32bit = aIntegralImageStride / 4;
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IntSize integralImageSize(aSize.width + aLeftInflation + aRightInflation,
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aSize.height + aTopInflation + aBottomInflation);
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LoadIntegralRowFromRow(aIntegralImage, aSource, aSize.width, aLeftInflation, aRightInflation);
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for (int y = 1; y < aTopInflation + 1; y++) {
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uint32_t *intRow = aIntegralImage + (y * stride32bit);
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uint32_t *intPrevRow = aIntegralImage + (y - 1) * stride32bit;
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uint32_t *intFirstRow = aIntegralImage;
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for (int x = 0; x < integralImageSize.width; x += 4) {
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uint32x4_t firstRow = vld1q_u32(intFirstRow + x);
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uint32x4_t previousRow = vld1q_u32(intPrevRow + x);
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vst1q_u32(intRow + x, vaddq_u32(firstRow, previousRow));
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}
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}
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for (int y = aTopInflation + 1; y < (aSize.height + aTopInflation); y++) {
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uint32x4_t currentRowSum = vdupq_n_u32(0);
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uint32_t *intRow = aIntegralImage + (y * stride32bit);
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uint32_t *intPrevRow = aIntegralImage + (y - 1) * stride32bit;
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uint8_t *sourceRow = aSource + aSourceStride * (y - aTopInflation);
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uint32_t pixel = sourceRow[0];
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for (int x = 0; x < aLeftInflation; x += 4) {
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uint32_t temp[4];
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temp[0] = pixel;
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temp[1] = temp[0] + pixel;
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temp[2] = temp[1] + pixel;
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temp[3] = temp[2] + pixel;
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uint32x4_t sumPixels = vld1q_u32(temp);
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sumPixels = vaddq_u32(sumPixels, currentRowSum);
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currentRowSum = vdupq_n_u32(vgetq_lane_u32(sumPixels, 3));
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vst1q_u32(intRow + x, vaddq_u32(sumPixels, vld1q_u32(intPrevRow + x)));
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}
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for (int x = aLeftInflation; x < (aSize.width + aLeftInflation); x += 4) {
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// It's important to shuffle here. When we exit this loop currentRowSum
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// has to be set to sumPixels, so that the following loop can get the
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// correct pixel for the currentRowSum. The highest order pixel in
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// currentRowSum could've originated from accumulation in the stride.
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currentRowSum = vdupq_n_u32(vgetq_lane_u32(currentRowSum, 3));
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uint32_t temp[4];
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temp[0] = *(sourceRow + (x - aLeftInflation));
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temp[1] = temp[0] + *(sourceRow + (x - aLeftInflation) + 1);
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temp[2] = temp[1] + *(sourceRow + (x - aLeftInflation) + 2);
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temp[3] = temp[2] + *(sourceRow + (x - aLeftInflation) + 3);
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uint32x4_t sumPixels = vld1q_u32(temp);
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sumPixels = vaddq_u32(sumPixels, currentRowSum);
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currentRowSum = sumPixels;
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vst1q_u32(intRow + x, vaddq_u32(sumPixels, vld1q_u32(intPrevRow + x)));
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}
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pixel = sourceRow[aSize.width - 1];
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int x = (aSize.width + aLeftInflation);
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if ((aSize.width & 3)) {
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// Deal with unaligned portion. Get the correct pixel from currentRowSum,
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// see explanation above.
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uint32_t intCurrentRowSum = ((uint32_t*)¤tRowSum)[(aSize.width % 4) - 1];
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for (; x < integralImageSize.width; x++) {
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// We could be unaligned here!
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if (!(x & 3)) {
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// aligned!
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currentRowSum = vdupq_n_u32(intCurrentRowSum);
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break;
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}
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intCurrentRowSum += pixel;
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intRow[x] = intPrevRow[x] + intCurrentRowSum;
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}
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} else {
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currentRowSum = vdupq_n_u32(vgetq_lane_u32(currentRowSum, 3));
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}
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for (; x < integralImageSize.width; x += 4) {
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uint32_t temp[4];
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temp[0] = pixel;
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temp[1] = temp[0] + pixel;
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temp[2] = temp[1] + pixel;
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temp[3] = temp[2] + pixel;
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uint32x4_t sumPixels = vld1q_u32(temp);
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sumPixels = vaddq_u32(sumPixels, currentRowSum);
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currentRowSum = vdupq_n_u32(vgetq_lane_u32(sumPixels, 3));
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vst1q_u32(intRow + x, vaddq_u32(sumPixels, vld1q_u32(intPrevRow + x)));
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}
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}
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if (aBottomInflation) {
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// Store the last valid row of our source image in the last row of
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// our integral image. This will be overwritten with the correct values
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// in the upcoming loop.
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LoadIntegralRowFromRow(aIntegralImage + (integralImageSize.height - 1) * stride32bit,
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aSource + (aSize.height - 1) * aSourceStride, aSize.width, aLeftInflation, aRightInflation);
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for (int y = aSize.height + aTopInflation; y < integralImageSize.height; y++) {
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uint32_t *intRow = aIntegralImage + (y * stride32bit);
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uint32_t *intPrevRow = aIntegralImage + (y - 1) * stride32bit;
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uint32_t *intLastRow = aIntegralImage + (integralImageSize.height - 1) * stride32bit;
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for (int x = 0; x < integralImageSize.width; x += 4) {
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vst1q_u32(intRow + x,
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vaddq_u32(vld1q_u32(intLastRow + x),
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vld1q_u32(intPrevRow + x)));
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}
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}
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}
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}
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/**
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* Attempt to do an in-place box blur using an integral image.
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*/
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void
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AlphaBoxBlur::BoxBlur_NEON(uint8_t* aData,
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int32_t aLeftLobe,
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int32_t aRightLobe,
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int32_t aTopLobe,
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int32_t aBottomLobe,
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uint32_t *aIntegralImage,
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size_t aIntegralImageStride)
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{
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IntSize size = GetSize();
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MOZ_ASSERT(size.height > 0);
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// Our 'left' or 'top' lobe will include the current pixel. i.e. when
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// looking at an integral image the value of a pixel at 'x,y' is calculated
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// using the value of the integral image values above/below that.
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aLeftLobe++;
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aTopLobe++;
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int32_t boxSize = (aLeftLobe + aRightLobe) * (aTopLobe + aBottomLobe);
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MOZ_ASSERT(boxSize > 0);
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if (boxSize == 1) {
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return;
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}
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uint32_t reciprocal = uint32_t((uint64_t(1) << 32) / boxSize);
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uint32_t stride32bit = aIntegralImageStride / 4;
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int32_t leftInflation = RoundUpToMultipleOf4(aLeftLobe).value();
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GenerateIntegralImage_NEON(leftInflation, aRightLobe, aTopLobe, aBottomLobe,
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aIntegralImage, aIntegralImageStride, aData,
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mStride, size);
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uint32x2_t divisor = vdup_n_u32(reciprocal);
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// This points to the start of the rectangle within the IntegralImage that overlaps
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// the surface being blurred.
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uint32_t *innerIntegral = aIntegralImage + (aTopLobe * stride32bit) + leftInflation;
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IntRect skipRect = mSkipRect;
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int32_t stride = mStride;
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uint8_t *data = aData;
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for (int32_t y = 0; y < size.height; y++) {
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bool inSkipRectY = y > skipRect.y && y < skipRect.YMost();
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uint32_t *topLeftBase = innerIntegral + ((y - aTopLobe) * ptrdiff_t(stride32bit) - aLeftLobe);
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uint32_t *topRightBase = innerIntegral + ((y - aTopLobe) * ptrdiff_t(stride32bit) + aRightLobe);
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uint32_t *bottomRightBase = innerIntegral + ((y + aBottomLobe) * ptrdiff_t(stride32bit) + aRightLobe);
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uint32_t *bottomLeftBase = innerIntegral + ((y + aBottomLobe) * ptrdiff_t(stride32bit) - aLeftLobe);
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int32_t x = 0;
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// Process 16 pixels at a time for as long as possible.
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for (; x <= size.width - 16; x += 16) {
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if (inSkipRectY && x > skipRect.x && x < skipRect.XMost()) {
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x = skipRect.XMost() - 16;
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// Trigger early jump on coming loop iterations, this will be reset
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// next line anyway.
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inSkipRectY = false;
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continue;
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}
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uint32x4_t topLeft;
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uint32x4_t topRight;
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uint32x4_t bottomRight;
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uint32x4_t bottomLeft;
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topLeft = vld1q_u32(topLeftBase + x);
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topRight = vld1q_u32(topRightBase + x);
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bottomRight = vld1q_u32(bottomRightBase + x);
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bottomLeft = vld1q_u32(bottomLeftBase + x);
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uint16x4_t result1 = BlurFourPixels(topLeft, topRight, bottomRight, bottomLeft, divisor);
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topLeft = vld1q_u32(topLeftBase + x + 4);
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topRight = vld1q_u32(topRightBase + x + 4);
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bottomRight = vld1q_u32(bottomRightBase + x + 4);
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bottomLeft = vld1q_u32(bottomLeftBase + x + 4);
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uint16x4_t result2 = BlurFourPixels(topLeft, topRight, bottomRight, bottomLeft, divisor);
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topLeft = vld1q_u32(topLeftBase + x + 8);
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topRight = vld1q_u32(topRightBase + x + 8);
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bottomRight = vld1q_u32(bottomRightBase + x + 8);
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bottomLeft = vld1q_u32(bottomLeftBase + x + 8);
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uint16x4_t result3 = BlurFourPixels(topLeft, topRight, bottomRight, bottomLeft, divisor);
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topLeft = vld1q_u32(topLeftBase + x + 12);
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topRight = vld1q_u32(topRightBase + x + 12);
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bottomRight = vld1q_u32(bottomRightBase + x + 12);
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bottomLeft = vld1q_u32(bottomLeftBase + x + 12);
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uint16x4_t result4 = BlurFourPixels(topLeft, topRight, bottomRight, bottomLeft, divisor);
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uint8x8_t combine1 = vqmovn_u16(vcombine_u16(result1, result2));
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uint8x8_t combine2 = vqmovn_u16(vcombine_u16(result3, result4));
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uint8x16_t final = vcombine_u8(combine1, combine2);
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vst1q_u8(data + stride * y + x, final);
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}
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// Process the remaining pixels 4 bytes at a time.
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for (; x < size.width; x += 4) {
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if (inSkipRectY && x > skipRect.x && x < skipRect.XMost()) {
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x = skipRect.XMost() - 4;
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// Trigger early jump on coming loop iterations, this will be reset
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// next line anyway.
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inSkipRectY = false;
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continue;
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}
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uint32x4_t topLeft = vld1q_u32(topLeftBase + x);
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uint32x4_t topRight = vld1q_u32(topRightBase + x);
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uint32x4_t bottomRight = vld1q_u32(bottomRightBase + x);
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uint32x4_t bottomLeft = vld1q_u32(bottomLeftBase + x);
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uint16x4_t result = BlurFourPixels(topLeft, topRight, bottomRight, bottomLeft, divisor);
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uint32x2_t final = vreinterpret_u32_u8(vmovn_u16(vcombine_u16(result, vdup_n_u16(0))));
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*(uint32_t*)(data + stride * y + x) = vget_lane_u32(final, 0);
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}
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}
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}
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}
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}
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